Lumbo-sacral neural crest contributes to the avian enteric nervous system independently of vagal neural crest.

Most of the avian enteric nervous system is derived from the vagal neural crest, but a minority of the neural cells in the hindgut, and to an even lesser extent in the midgut, are of lumbo-sacral crest origin. Since the lumbo-sacral contribution was not detected or deemed negligible in the absence of vagal cells, it had been hypothesised that lumbo-sacral neural crest cells require vagal crest cells to contribute to the enteric nervous system. In contrast, zonal aganglionosis, a rare congenital human bowel disease led to the opposite suggestion, that lumbo-sacral cells could compensate for the absence of vagal cells to construct a complete enteric nervous system. To test these notions, we combined E4 chick midgut and hindgut, isolated prior to arrival of neural precursors, with E1. 7 chick vagal and/or E2.7 quail lumbo-sacral neural tube as crest donors, and grafted these to the chorio-allantoic membrane of E9 chick hosts. Double and triple immuno-labelling for quail cells (QCPNA), neural crest cells (HNK-1), neurons and neurites (neurofilament) and glial cells (GFAP) indicated that vagal crest cells produced neurons and glia in large ganglia throughout the entire intestinal tissues. Lumbo-sacral crest contributed small numbers of neurons and glial cells in the presence or absence of vagal cells, chiefly in colorectum, but not in nearby small intestinal tissue. Thus for production of enteric neural cells the avian lumbo-sacral neural crest neither requires the vagal neural crest, nor significantly compensates for its lack. However, enteric neurogenesis of lumbo-sacral cells requires the hindgut microenvironment, whereas that of vagal cells is not restricted to a particular intestinal region.     

Immunophenotypic characterization of enteric neural crest cells in the developing avian colorectum

Background: The enteric nervous system (ENS) develops from neural crest‐derived cells that migrate along the intestine to form two plexuses of neurons and glia. While the major features of ENS development are conserved across species, minor differences exist, especially in the colorectum. Given the embryologic and disease‐related importance of the distal ENS, the aim of this study was to characterize the migration and differentiation of enteric neural crest‐derived cells (ENCCs) in the colorectum of avian embryos. Results: Using normal chick embryos and vagal neural tube transplants from green fluorescent protein (GFP) ‐transgenic chick embryos, we find ENCCs entering the colon at embryonic day (E) 6.5, with colonization complete by E8. Undifferentiated ENCCs at the wavefront express HNK‐1, N‐cadherin, Sox10, p75, and L1CAM. By E7, differentiation begins in the proximal colon, with L1CAM and Sox10 becoming restricted to neuronal and glial lineages, respectively. By E8, multiple markers of differentiation are expressed along the entire colorectum. Conclusions: Our results establish the pattern of ENCC migration and differentiation in the chick colorectum, demonstrate the conservation of marker expression across species, highlight a range of markers, including neuronal cell adhesion molecules, which label cells at the wavefront, and provide a framework for future studies in avian ENS development. Developmental Dynamics 241:842–851, 2012. © 2012 Wiley Periodicals, Inc.     

Immunophenotypic characterization of enteric neural crest cells in the developing avian colorectum

A chick–chick intraspecies chimera was created by removing the neural tube adjacent to somites 2–6 from a normal chick embryo at E1.5 and replacing it with equivalent tissue from an age‐matched chick‐GFP transgenic embryo. At E10, the colorectum was removed, sectioned, and stained with HNK‐1 antibody (red) to detect neural crest‐derived cells, and with DAPI (blue) to label nuclei. Vagal neural crest‐derived cells are HNK‐1+/GFP+, while sacral neural crest derived‐cells, which comprise the nerve of Remak, are HNK‐1+/GFP?. From Nagy et al., Developmental Dynamics 241:842–851, 2012. © 2012 Wiley Periodicals, Inc.     

Balancing neural crest cell intrinsic processes with those of the microenvironment in Tcof1 haploinsufficient mice enables complete enteric nervous system formation

The enteric nervous system (ENS) comprises a complex neuronal network that regulates peristalsis of the gut wall and secretions into the lumen. The ENS is formed from a multipotent progenitor cell population called the neural crest, which is derived from the neuroepithelium. Neural crest cells (NCCs) migrate over incredible distances to colonize the entire length of the gut and during their migration they must survive, proliferate and ultimately differentiate. The absence of an ENS from variable lengths of the colon results in Hirschsprung's disease (HSCR) or colonic aganglionosis. Mutations in about 12 different genes have been identified in HSCR patients but the complex pattern of inheritance and variable penetrance suggests that additional genes or modifiers must be involved in the etiology and pathogenesis of this disease. We discovered that Tcof1 haploinsufficiency in mice models many of the early features of HSCR. Neuroepithelial apoptosis diminished the size of the neural stem cell pool resulting in reduced NCC numbers and their delayed migration along the gut from E10.5 to E14.5. Surprisingly however, we observe continued and complete colonization of the entire colon throughout E14.5-E18.5, a period in which the gut is considered to be non- or less-permissive to NCC. Thus, we reveal for the first time that reduced NCC progenitor numbers and delayed migration do not unequivocally equate with a predisposition for the pathogenesis of HSCR. In fact, these deficiencies can be overcome by balancing NCC intrinsic processes of proliferation and differentiation with extrinsic influences of the gut microenvironment.     

Ageing of the enteric nervous system

The intrinsic neurones of the enteric nervous system (ENS) play a fundamental role in the regulation of gastrointestinal functions. Although much remains to be learnt about the changes that take place in intestinal nerves during ageing, evidence suggests that selective neurodegeneration may occur in the ageing ENS. Age-associated changes in intestinal innervation may contribute to the gastrointestinal disorders that increase in incidence in the elderly, such as dysphagia, gastrointestinal reflux and constipation. A number of other factors, such as immobility, co-morbidity, and side effects of therapeutic medication for other disorders however, are also likely to contribute to the aetiology of these conditions. An important finding in rodents is that the neuronal losses that take place in the ENS during ageing may be prevented by calorie restriction; an indication that diet may influence gastrointestinal ageing. Thus, it is of importance to understand not only how the ENS changes during 'normal' ageing, but also how external factors contribute to these changes. Here, current knowledge of how intestinal innervation is affected during normal ageing and how these changes may impact upon gastrointestinal physiology are reviewed.     

Disturbances of colonic ion secretion in inflammation: role of the enteric nervous system and cAMP

We used the trinitrobenzenesulphonic acid (TNBS) rat model of experimental colitis to study the alterations in electrogenic ion transport in the inflamed distal colon. The distal colon exhibited decreased basal transport and reduced short-circuit current responses to carbachol and isobutylmethylxanthine (IBMX). The concentration/response curve for IBMX was also shifted to the right. Ion substitution experiments indicated that electrogenic transport was attributable chiefly to Cl(-) secretion. The mucosal layer of the inflamed distal colon (devoid of the submucosa) exhibited normal maximal responses to carbachol and IBMX, although the concentration/response curve for the latter was again shifted to the right. Tetrodotoxin markedly increased the response of the normal distal colon to both secretagogues and nullified the inhibition of the response to carbachol, but not that to IBMX, in the inflamed colon. The response of the mucosal preparation to 8-bromoadenosine 3',5'-cyclic monophosphate was similar in the normal and inflamed intestine, while the G protein activator NaF had a greater effect in the latter. The expression of the cystic fibrosis transmembrane conductance regulator (CFTR), as assessed by Northern blotting, was unchanged. cAMP levels in isolated colonocytes were markedly reduced by inflammation. We conclude that colonic inflammation produces disturbances of the enteric nervous system resulting in defective mucosal cAMP production and inhibition of ionic secretion.     

Cardiac neural crest stem cells

Whereas the heart itself is of mesodermal origin, components of the cardiac outflow tract are formed by the neural crest, an ectodermal derivative that gives rise to the peripheral nervous system, endocrine cells, melanocytes of the skin and internal organs, and connective tissue, bone, and cartilage of the face and ventral neck, among other tissues. Cardiac neural crest cells participate in the septation of the cardiac outflow tract into aorta and pulmonary artery. The migratory cardiac neural crest consists of stem cells, fate-restricted cells, and cells that are committed to the smooth muscle cell lineage. During their migration within the posterior branchial arches, the developmental potentials of pluripotent neural crest cells become restricted. Conversely, neural crest stem cells persist at many locations, including in the cardiac outflow tract. Many aspects of neural crest cell differentiation are driven by growth factor action. Neurotrophin-3 (NT-3) and its preferred receptor, TrkC, play important roles not only in nervous system development and function, but also in cardiac development as deletion of these genes causes outflow tract malformations. In vitro clonal analysis has shown a premature commitment of cardiac neural crest stem cells in TrkC null mice and a perturbed morphology of the endothelial tube. Norepinephrine transporter (NET) function promotes the differentiation of neural crest stem cells into noradrenergic neurons. Surprisingly, many diverse nonneuronal embryonic tissues, in particular in the cardiovascular system, express NET also. It will be of interest to determine whether norepinephrine transport plays a role also in cardiovascular development.     

Gdnf is mitogenic,neurotrophic, and chemoattractive to enteric neural crest cells in the embryonic colon

Glial‐derived neurotrophic factor (Gdnf) is required for morphogenesis of the enteric nervous system (ENS) and it has been shown to regulate proliferation, differentiation, and survival of cultured enteric neural crest–derived cells (ENCCs). The goal of this study was to investigate its in vivo role in the colon, the site most commonly affected by intestinal neuropathies such as Hirschsprung's disease. Gdnf activity was modulated in ovo in the distal gut of avian embryos using targeted retrovirus‐mediated gene overexpression and retroviral vector‐based gene silencing. We find that Gdnf has a pleiotropic effect on colonic ENCCs, promoting proliferation, inducing neuronal differentiation, and acting as a chemoattractant. Down‐regulating Gdnf similarly induces premature neuronal differentiation, but also inhibits ENCC proliferation, leading to distal colorectal aganglionosis with severe proximal hypoganglionosis. These results indicate an important role for Gdnf signaling in colonic ENS formation and emphasize the critical balance between proliferation and differentiation in the developing ENS. Developmental Dynamics 240:1402–1411, 2011. © 2011 Wiley‐Liss, Inc.     

Pelvic plexus contributes ganglion cells to the hindgut enteric nervous system.

The hindgut enteric nervous system (ENS) contains cells originating from vagal and sacral neural crest. In avians, the sacral crest gives rise to the nerve of Remak (NoR) and pelvic plexus. Whereas the NoR has been suggested to serve as the source of sacral crest-derived cells to the gut, the contribution of the pelvic ganglia is unknown. The purpose of this study was to test the hypothesis that the pelvic ganglia contribute ganglion cells to the hindgut ENS. We observed that the quail pelvic plexus develops from neural crest-derived cells that aggregate around the cloaca at embryonic day 5. Using chick-quail tissue recombinations, we found that hindgut grafts did not contain enteric ganglia unless the pelvic plexus was included. Neurofibers extended from the NoR into the intestine, but no ganglion cell contribution from the NoR was identified. These results demonstrate that the pelvic plexus, and not the NoR, serves as the staging area for sacral crest-derived cells to enter the avian hindgut, confirming the evolutionary conservation of this important embryologic process.     

Enteric nervous system development: analysis of the selective developmental potentialities of vagal and sacral neural crest cells using quail-chick chimeras

The majority of the enteric nervous system (ENS) is derived from vagal neural crest cells (NCC). For many years, the contribution from a second region of the neuraxis (the sacral neural crest) to the ENS has been less clear, with conflicting reports appearing in the literature. To resolve this longstanding issue, we documented the spatiotemporal migration and differentiation of vagal and sacral-derived NCC within the developing chick embryo using quail-chick grafting and antibody labelling. Results showed that vagal NCC colonised the entire length of the gut in a rostrocaudal direction. The hindgut, the region of the gastrointestinal tract most frequently affected in developmental disorders, was found to be colonised in a complex manner. Vagal NCC initially migrated within the submucosa, internal to the circular muscle layer, before colonising the myenteric plexus region. In contrast, sacral NCC, which colonised the hindgut in a caudorostral direction, were primarily located in the myenteric plexus region from where they subsequently migrated to the submucosa. We also observed that sacral NCC migrated into the hindgut in significant numbers only after vagal-derived cells had colonised the entire length of the gut. This suggested that to participate in ENS formation, sacral cells may require an interaction with vagal-derived cells, or with factors or signalling molecules released by them or their progeny. To investigate this possible inter-relationship, we ablated sections of vagal neural crest (NC) to prevent the rostrocaudal migration of ENS precursors and, thus, create an aganglionic hindgut model. In the same NC ablated animals, quail-chick sacral NC grafts were performed. In the absence of vagal-derived ganglia, sacral NCC migrated and differentiated in an apparently normal manner. Although the numbers of sacral cells within the hindgut was slightly higher in the absence of vagal-derived cells, the increase was not sufficient to compensate for the lack of enteric ganglia. As vagal NCC appear to be more invasive than sacral NCC, since they colonise the entire length of the gut, we investigated the ability of transplanted vagal cells to colonise the hindgut by grafting the vagal NC into the sacral region. We found that when transplanted, vagal cells retained their invasive capacity and migrated into the hindgut in large numbers. Although sacral-derived cells normally contribute a relatively small number of precursors to the post-umbilical gut, many heterotopic vagal cells were found within the hindgut enteric plexuses at much earlier stages of development than normal. Heterotopic grafting of invasive vagal NCC into the sacral neuraxis may, therefore, be a means of rescuing an aganglionic hindgut phenotype.     

Types of nerves in the enteric nervous system

The enteric nervous system is one of the three divisions of the autonomic nervous system, the others being the sympathetic and parasympathetic. In contrast to the other divisions, it can perform many functions independently of the central nervous system. It consists of ganglionated plexuses, their connections with each other, and nerve fibres which arise from the plexuses and supply the muscle, blood vessels and mucosa of the gastrointestinal tract. The enteric nervous system contains a large number of neurons, approximately 10⁷ to 10⁸. About ten or more distinct types of enteric neurons have been distinguished on electrical, pharmacological, histochemical, biochemical and ultrastructural grounds as well as on the basis of their modes of action. Both excitatory and inhibitory nerves supply the muscle and there are inhibitory and excitatory interneurons within the enteric plexuses. There are also enteric nerves which supply intestinal glands and blood vessels, but these receive less emphasis in this commentary.Correlations between groups of neurons defined on different criteria are poor and in many cases the physiological roles of the nerves are not known. The functions of noradrenergic nerves which are of extrinsic origin are reasonably well understood, but cholinergic nerves in the intestine are the only intrinsic nerves for which both the transmitter and to some extent the functions are known. In the case of non-cholinergic, non-noradrenergic enteric inhibitory nerves, the functions are understood but the transmitter is yet to be determined, both adenosine 5′-triphosphate and vasoactive intestinal polypeptide having been proposed. Other nerves have been defined pharmacologically (non-cholinergic excitatory nerves to neurons and muscle, intrinsic inhibitory inputs to neurons, and enteric, non-cholinergic vasodilator nerves) and histochemically (intrinsic amine-handling neurons and separate neurons containing peptides: substance P, somatostatin, enkephalins, vasoactive intestinal polypeptide, gastrin cholecystokinin tetrapeptide, bombesin, neurotensin and probably other peptides). Little is known of the functions of these nerves, although a number of proposals which have been made are discussed.     

Hoxb3 vagal neural crest-specific enhancer element for controlling enteric nervous system development.

The neural and glial cells of the intrinsic ganglia of the enteric nervous system (ENS) are derived from the hindbrain neural crest at the vagal level. The Hoxb3 gene is expressed in the vagal neural crest and in the enteric ganglia of the developing gut during embryogenesis. We have identified a cis-acting enhancer element b3IIIa in the Hoxb3 gene locus. In this study, by transgenic mice analysis, we examined the tissue specificity of the b3IIIa enhancer element using the lacZ reporter gene, with emphasis on the vagal neural crest cells and their derivatives in the developing gut. We found that the b3IIIa-lacZ transgene marks only the vagal region and not the trunk or sacral region. Using cellular markers, we showed that the b3IIIa-lacZ transgene was expressed in a subset of enteric neuroblasts during early development of the gut, and the expression was maintained in differentiated neurons of the myenteric plexus at later stages. The specificity of the b3IIIa enhancer in directing gene expression in the developing ENS was further supported by genetic analysis using the Dom mutant, a spontaneous mouse model of Hirschsprung's disease characterized by the absence of enteric ganglia in the distal gut. The colonization of lacZ-expressing cells in the large intestine was incomplete in all the Dom/b3IIIa-lacZ hybrid mutants we examined. To our knowledge, this is the only vagal neural crest-specific genetic regulatory element identified to date. This element could be used for a variety of genetic manipulations and in establishing transgenic mouse models for studying the development of the ENS.     

Distribution of different regions of cardiac neural crest in the extrinsic and the intrinsic cardiac nervous system.

In this study we focused upon whether different levels of postotic neural crest as well as the right and left cardiac neural crest show a segmented or mixed distribution in the extrinsic and intrinsic cardiac nervous system. Different parts of the postotic neural crest were labeled by heterospecific replacement of chick neural tube by its quail counterpart. Quail-chick chimeras (n = 21) were immunohistochemically evaluated at stage HH28+, HH29+, and between HH34-37. In another set of embryos, different regions of cardiac neural crest were tagged with a retrovirus containing the LacZ reporter gene and evaluated between HH35-37 (n = 13). The results show a difference in distribution between the right- and left-sided cardiac neural crest cells at the arterial pole and ventral cardiac plexus. In the dorsal cardiac plexus, the right and left cardiac neural crest cells mix. In general, the extrinsic and intrinsic cardiac nerves receive a lower contribution from the right cardiac neural crest compared with the left cardiac neural crest. The right-sided neural crest from the level of somite 1 seeds only the cranial part of the vagal nerve and the ventral cardiac plexus. Furthermore, the results show a nonsegmented overlapping contribution of neural crest originating from S1 to S3 to the Schwann cells of the cranial and recurrent nerves and the intrinsic cardiac plexus. Also the Schwann cells along the distal intestinal part of the vagal nerve are derived exclusively from the cardiac neural crest region. These findings and the smaller contribution of the more cranially emanating cardiac neural crest to the dorsal cardiac plexus compared with more caudal cardiac neural crest levels, suggests an initial segmented distribution of cardiac neural crest cells in the circumpharyngeal region, followed by longitudinal migration along the vagal nerve during later stages.     

Prostaglandin I2 sensory input into the enteric nervous system during distension-induced colonic chloride secretion in rat colon

Aim: Intestinal pressure differences or experimental distension induce ion secretion via the enteric nervous system, the sensorial origin of which is only poorly understood. This study aimed to investigate sensorial inputs and the role of afferent and interneurones in mechanically activated submucosal secretory reflex circuits. Methods: Distension-induced rheogenic chloride secretion was measured as increase in short-circuit current 10 min after distension (ΔI_SC¹⁰; distension parameters ± 100 μL, 2 Hz, 20 s) in partially stripped rat distal colon in the Ussing-chamber in vitro. PGE₂ and PGI₂ were measured by radioimmunoassay. Results: ΔI_SC¹⁰ was 2.0 ± 0.2 μmol h⁻¹ cm⁻² and could be attenuated by lobeline, mecamylamine and dimethylphenylpiperazine, indicating an influence of nicotinergic interneurones. Additionally, a contribution of afferent neurones was indicated from the short-term potentiation of ΔI_SC¹⁰ by capsaicin (1 μm ). As evidence for its initial event, indomethacin (1 μm ) inhibited distension-induced secretion and the release of PGI₂ was directly detected after distension. Furthermore, serotoninergic mediation was confirmed by granisetron (100 μm ) which was functionally localized distally to PGI₂ in this reflex circuit, as granisetron inhibited an iloprost-induced I_SC, while indomethacin did not affect serotonin-activated ion secretion. Conclusions: Distension-induced active electrogenic chloride secretion in rat colon is mediated by a neuronal reflex circuit which includes afferent neurones and nicotinergic interneurones. It is initiated by distension-induced PGI₂ release from subepithelial cells triggering this reflex via serotoninergic 5-HT₃ receptor transmission. Functionally, this mechanism may help to protect against intestinal stasis but could also contribute to luminal fluid loss, e.g. during intestinal obstruction.     

Neural crest as the source of adult stem cells

Recent studies suggest that adult stem cells can cross germ layer boundaries. For example, bone marrow-derived stem cells appear to differentiate into neurons and glial cells, as well as other types of cells. How can stem cells from bone marrow, pancreas, skin, or fat become neurons and glia; in other words, what molecular and cellular events direct mesodermal cells to a neural fate? Transdifferentiation, dediffereniation, and fusion of donor adult stem cells with fully differentiated host cells have been proposed to explain the plasticity of adult stem cells. Here we review the origin of select adult stem cell populations and propose a unifying hypothesis to explain adult stem cell plasticity. In addition, we outline specific experiments to test our hypothesis. We propose that peripheral, tissue-derived, or adult stem cells are all progeny of the neural crest.     

The involvement of the interstitial Cajal cells and the enteric nervous system in bowel endometriosis

BACKGROUND: Our aim was to investigate the relationships between gastrointestinal symptoms and histological findings in women with bowel endometriosis. METHODS: The gastrointestinal symptoms of 362 women with endometriosis were classified according to the subgroups of the Rome II criteria. All visible endometriotic lesions of the bowel were removed; the patients were prospectively followed up for 2 years. The interstitial Cajal cells (ICC) and the enteric nervous system were immunohistochemically evaluated. RESULTS: Sixty-eight (18.8%, 95% CI 14.9-23.2) women had bowel lesions. The endometriotic lesions infiltrated the serosal layer and surrounding connective tissue in 45 cases; the subserous plexus in 11 cases; the Auerbach plexus in eight cases; the Meissner plexus in four cases. Whenever the subserous plexus was interrupted by the endometriotic lesions, the ICC were damaged. All women with endometriotic lesions reaching at least the subserous plexus reported bowel complaints. The level of infiltration into the bowel wall was correlated with severity of symptoms. Removal of lesions resulted in improvement of symptoms. CONCLUSIONS: Endometriosis-induced damage of ICC, even before muscular infiltration, may cause bowel symptoms.